Circuit breaker for DC circuits using coupled induction

ABSTRACT

An improved DC circuit breaker is provided for automatically detecting and isolating a fault between a source and a ground. The DC circuit breaker comprises at least one switch, in electrical series with a first inductor between the source and a load, and a second inductor magnetically coupled to the first inductor wherein a first side of the second inductor is electrically connected to the load and a second side of the second inductor is grounded through a capacitor.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims priority to U.S. Provisional Patent Appl.No. 62/101,423 filed Jan. 9, 2015, which is incorporated herein byreference.

BACKGROUND

The present invention is directed to a new type of solid-state breakerthat uses magnetic coupling instead of a crossed connection toaccomplish an automatic response to an electrical fault.

Since the great debate between Thomas Edison and Nikola Tesla ournations power system has operated on alternating current (AC). This waschosen over direct current (DC) because of the need to step up thevoltage to a high value using transformers for long-distance powertransmission. Traditional transformers available at the time onlyoperated on AC. Nowadays, many energy sources such as solar panels, fuelcells, batteries, etc. supply a DC voltage. Also, DC/DC power convertersare common-place for transforming the voltage and interfacing these DCsources to a larger system. Because of this, local DC power systems, ormicro grids, have become increasingly more popular. Furthermore,interfacing a wind power generator to a DC system is much simpler thaninterfacing to an AC system since an AC/DC conversion is needed for theformer and an AC/DC/AC conversion is needed for the latter. Although theenergy sources and power conversion is readily available for DC powersystems, circuit breakers are not. Breaking an AC circuit is much easierthan breaking a DC circuit. The DC circuit has a constant currentwithout a zero crossing, and thus breaking this circuit causes arcingthat cannot be extinguished. Options for making a DC circuit breakerinclude a hybrid mechanical/electrical design, a solid state breaker,and z-source breakers as described herein.

C. Meyer, M. Kowal, and R. W. De Doncker, “Circuit Breaker Concepts forFuture High-Power DC-Applications,” IEEE Industry Applications SocietyConference, volume 2, pages 860-866, 2005 describes a hybridmechanical/electrical breaker. A mechanical switch is placed in parallelwith solid-state devices. During normal operation, the mechanical switchconducts the main current. A fault detection circuit opens themechanical switch and diverts the current through a power transistor,then to a metal-oxide varistor. This device clamps the breaker voltageuntil the fault current can be reduced by the system inductance. Theprimary advantage of the hybrid breaker is low power losses duringnormal operation. A disadvantage of this circuit is the time needed forfault detection and switch turn-off leading to the source therefore asignificant amount of current can be experienced before the fault can beisolated.

A. Pokryvailo and I. Ziv, “A Hybrid Repetitive Opening Switch ForInductive Storage Systems And Protection Of Dc Circuits,” IEEE PowerModulator Symposium, High-Voltage Workshop, pages 612-615, 2002demonstrates a solid-state breaker. A silicon-controlled rectifier (SCR)conducts the current. A resonant L-C circuit is also part of the breakerand has the capacitor pre-charged. Upon detection of a fault, asecondary switch places the L-C circuit in parallel with the SCR. Thiscauses a resonance whereby the SCR current goes to zero and the SCRswitches off; isolating the faulty load. After opening, a thirdinductive branch is connected to the L-C circuit causing a reversal ofpolarity in the capacitor so that the breaker is reset and ready foroperation again. The solid-state breaker offers fast switching timeswhich is important in DC power systems so that the source current doesnot build up to excessive levels. The primary disadvantage of thiscircuit is the on-state power losses.

R. Schmerda, R. Cuzner, R. Clark, D. Nowak, and S. Bunzel, “ShipboardSolid-State Protection: Overview and Applications,” IEEE ElectrificationMagazine, volume 1, issue 1, pages 32-39, 2013 presents a special typeof solid-state circuit breaker. After fault detection, a main pathtransistor disconnects the faulty load. This circuit has an additionaldiode path which picks up the load current after the source isdisconnected. The concept has been extensively developed and tested forNaval shipboard power systems. This circuit has an advantage of beingextremely fast. Normal on-state power losses are an issue as is the needfor fault detection.

K. A. Corzine and R. W. Ashton, “A New Z-Source Dc Circuit Breaker,”IEEE Transactions on Power Electronics, volume 27, number 6, pages2796-2804, June 2012 introduced a new concept in the solid-state breakercircuits called the z-source breaker. An added crossed connection ofinductors and capacitors causes the breaker to automatically switch offin response to a transient change in the load current. This circuit hasthe advantage of quick fault isolation that is typical of solid-statebreakers. This circuit has the additional advantage that detection ofthe fault is not necessary. Furthermore, the source does not experiencea fault current and instead, the source current is pushed to zero duringa fault. The primary disadvantage of this circuit is the on-state powerlosses.

A. H. Chang, A. Avestruz, S. B. Leeb, and J. L. Kirtley, “Design of DCSystem Protection,” IEEE Electric Ship Technologies Symposium, pages500-508, April 2013. Shortly after the introduction of the z-sourcebreaker, this group of MIT researchers presented a variation. Theprimary advantage of this circuit is that it has a common-groundconnection between the source and load and has the desirable frequencyresponse property of a low-pass filter.

FIG. 1A shows a typical arrangement of a circuit breaker insertedbetween a source and load. In this circuit, the source current ismonitored for fault current detection. Alternatively, a capacitor can beconnected to ground within the breaker as shown in FIG. 1B. This methodis good for detecting transient currents and is used in motor drives fordetection of shoot-through. That is, a small capacitor in series withsome type of current sensor can be connected to the DC bus of a drive.Shoot-through faults create an impulse of current in this capacitor andthe detection can immediately switch off the drive's gate signals.Likewise, a short path could be added to any type of DC circuit breakerfor fast detection of faults. Instead of monitoring the main pathcurrent (between source and load) and allowing the source to experiencethe fault current for a while, the short path between the addedcapacitor and load readily indicates the fault.

In spite of the ongoing effort those of skill in the art still do nothave a suitable option for a circuit breaker suitable for DCapplications. An improved DC circuit breaker is provided herein.

SUMMARY OF THE INVENTION

It is an object of the invention to provide a circuit breaker for DCapplications.

It is an object of the invention to circuit breaker for DC applicationswhich minimizes parasitic power loss in use and can rapidly andautomatically isolate a fault.

These and other advantages, as will be realized, are provided in a DCcircuit breaker for automatically detecting and isolating a faultbetween a source and a ground. The DC circuit breaker comprises at leastone switch, in electrical series with a first inductor between thesource and a load, and a second inductor magnetically coupled to thefirst inductor wherein a first side of the second inductor iselectrically connected to the load and a second side of the secondinductor is grounded through a capacitor.

Yet another embodiment is provided in a DC circuit breaker forautomatically detecting and isolating a fault between a source and aground. The DC circuit breaker comprises at least one switch inelectrical series between the source and a first side of a firstinductor; and a second inductor magnetically coupled to the firstinductor wherein a first side of said second inductor is groundedthrough a capacitor and the first side of the second inductor is inelectrical series with the first inductor and a second side of thesecond inductor is in electrical contact with load.

FIGURES

FIGS. 1A and 1B schematically illustrate fault sensing techniques usinga path from the source or from the breaker.

FIG. 2 is a schematic representation of a DC circuit breaker.

FIG. 3 is a schematic representation of a DC circuit breaker.

FIG. 4 is a schematic representation of an equivalent circuit of a DCbreaker.

FIG. 5 graphically illustrates the voltage transfer function of a DCbreaker.

FIG. 6 graphically illustrates Thevenin impedance of a DC breaker.

FIG. 7 graphically illustrates an embodiment of the invention.

FIG. 8 graphically illustrates an embodiment of the invention.

FIG. 9 graphically illustrates a measured response to a step change inload.

FIG. 10 graphically illustrates a measured response to a fault.

FIG. 11 is a schematic representation of a DC circuit breaker.

FIG. 12 graphically illustrates a simulation demonstration of switch-offcapability.

FIG. 13 graphically illustrates a simulation demonstration of faulthandling.

DESCRIPTION

The instant invention is specific to solid-state DC circuit breakersthat use magnetic coupling instead of a crossed connection to accomplishan automatic response to an electrical fault. The present inventionprovides a number of advantages. The common ground is connected fromsource to load and the source current goes to zero in response to anelectrical fault without ringing. The inventive circuit has fewer partsthan a z-source breaker and other solid-state breakers. This makes foreasier manufacturing and higher reliability. The turns ratio of themagnetically coupled circuit can be used to set a threshold level forthe fault current therefore the circuit breaker will not respond tolarge changes in load but will still isolate faults.

The invention will be described with reference to the various figureswhich form an integral non-limiting component of the disclosure.Throughout the disclosure similar elements will be numbered accordingly.

An embodiment of the invention will be described with reference to FIG.2 wherein an inventive DC circuit breaker is illustrated schematically.During normal steady-state operation, current flows from the source tothe load through the SCR and coupled inductors. A fault on the load sidewill cause an impulse current i_(c) in the short path containing thecapacitor and secondary winding of the coupled inductors. Based on theturns ratio, this current is reflected to the primary and essentiallypushes the SCR current to zero; at which time the SCR switches off. Itshould be noted that the turns ratio N₁/N₂ can also be set so that theDC circuit breaker does not identify a large change in load as a fault.

An embodiment of the invention is illustrated in schematic view in FIG.3. In this circuit, the main path current flows through the primary andsecondary windings. As with the circuit of FIG. 2, the fault currentflows through the secondary winding and causes the SCR current to go tozero.

In FIGS. 2 and 3 the top inductor is referred to as the first inductorand the bottom inductor is referred to as the second inductor for thepurposes of clarity in describing the figures. First and second sidesare defined for convenience. An optional rectifier is in electricalparallel with the first inductor to minimize ringing. The resistor inthe short path, between the appropriate inductor and capacitor to groundcan represent a passive or active electronic component such as, but notlimited to resistors, inductors, capacitors, varistors, diodes,semi-conductor switches, memresistors and the like. The SCR represents aswitch selected from a silicon-controlled rectifier, an insulated-gatebipolar transistor (IGBT) a metal-oxide-semiconductor field-effecttransistor and a mechanical switch. More preferably, the SCR representsa switch selected from a silicon-controlled rectifier and aninsulated-gate bipolar transistor with a silicon controlled rectifierbeing most preferred.

One of the main features of the inventive DC switch is its ability toremain on during a step change in load. This is accomplished by thedesign of the transformer component as further described herein. FromFIG. 2, and neglecting transformer magnetizing current,

$\begin{matrix}{i_{s} = {i_{0} - {\frac{N_{2}}{N_{1}}i_{c}}}} & (1)\end{matrix}$

For steady-state operation, the capacitor current is zero and the sourcecurrent is equal to the output current. Assuming that a sudden change inoutput current is entirely represented by a change in capacitor current,that is,Δi _(c) ≈Δi _(o)  (2)by transformer action,

$\begin{matrix}{i_{s} \approx {{- \frac{N_{2}}{N_{1}}}i_{c}} \approx {{- \frac{N_{2}}{N_{1}}}i_{o}}} & (3)\end{matrix}$and with an initial output current ofi _(s) =I _(o)  (4)the response of the source current to a change in output current will be

$\begin{matrix}{i_{s} = {I_{o} - {\frac{N_{2}}{N_{1}}\Delta\;{i_{o}.}}}} & (5)\end{matrix}$

The source current, and thus the SCR current, will go to zero when thechange in output meets the condition

$\begin{matrix}{{\Delta\; i_{o}} > {\frac{N_{2}}{N_{1}}I_{o}}} & (6)\end{matrix}$therefore, equation (6) can be used to determine the amount of change inoutput current that will result in the breaker switching off. This canalso be used to select a turns ratio to ensure that the breaker will notswitch off during expected load transients.

The breaker design starts with choosing a wire size and carrying out adesign for the transformer primary winding. For the purposes ofillustration a wire with a diameter of 0.82 mm² is considered. For thisnon-limiting illustrative design, the transformer is an air-core typewound around a square capacitor having dimensions of 70 mm by 57.5 mmfor the purposes of illustration without limit thereto. A number ofturns is selected and 5% leakage inductance is assumed for the instantexamples without limit thereto. The resulting parameters are displayedin Table I. In this case a turns ratio of 3 is selected so that thetransient load current can step by 300% without switching the breakeroff. Turn ratios of 1/100 to 100 can be employed to optimize theanticipated transient load. Using the same wire size as the primary, thesecondary parameters are computed and shown in Table I. In this design,the SCR total turn-off time t_(q) is taken into account and theresonance formed by L_(m2) and C is set so that a quarter cycle is threetimes the turn-off time. This results in the value of capacitance inTable I. The resistance is set to a low value as not to interfere withthe breaker performance, but still able to provide damping of theoscillations which occur when the breaker is switched off. The last rowof Table I shows the SCR ratings based on a 100V 6 A DC load which iswithin the ratings of the selected SCR.

TABLE I Parameters of the test system. N₁ = 70 r₁ = 0.373 Ω L_(l1) = 51μH L_(m1) = 960 μH C = 100 μF N₂ = 24 r₂ = 0.128 Ω L_(l2) = 6 μH L_(m2)= μH R = 0.2 Ω V_(RRM) = 400 V I_(TRMS) = 40 A t_(q) = 35 us

FIG. 4 shows the equivalent circuit of the inventive breaker with theSCR conducting. In this circuit, the transformer resistance and leakageinductance are neglected.

In the equivalent circuit illustrated in FIG. 4 Z_(RC) is the seriescombination of R and C. Z_(L) is the parallel combination of R_(I) andC_(I). Furthermore, L_(m1) and L_(m2) are the primary and secondarymagnetizing inductances of the transformer respectively. From theequivalent circuit, it can be determined that the voltage transferfunction is

$\begin{matrix}{\frac{v_{o}}{v_{s}} = \frac{{s\left( {L_{m\; 2} - L_{12}} \right)} + Z_{RC}}{{s\left( {\frac{L_{m\; 1}Z_{RC}}{Z_{L}} + L_{m\; 1} + L_{m\; 2} - {2L_{12}}} \right)} + Z_{RC}}} & (7)\end{matrix}$and the impedance as seen from the source is

$\begin{matrix}{\frac{v_{s}}{i_{s}} = \frac{{s\left( {\frac{L_{m\; 1}Z_{RC}}{Z_{L}} + L_{m\; 1} + L_{m\; 2} - {2L_{12}}} \right)} + Z_{RC}}{{s\left( {\frac{L_{m\; 2}}{Z_{L}} + \frac{L_{m\; 2}}{Z_{RC}} - \frac{L_{12}^{2}}{L_{m\; 1}Z_{RC}}} \right)} + \frac{Z_{RC}}{Z_{L}} + 1}} & (8)\end{matrix}$whereL ₁₂=√{square root over (L _(m1) L _(m2))}  (9)

FIG. 5 shows the voltage transfer function according to (7) for theproposed breaker with parameters in Table I. In this example, R_(I)=50 Ωand C_(I)=O. At low frequencies, the inventive DC circuit breaker hasunity gain. There is a resonance around 800 Hz and the breakerattenuates signals of higher frequency. The transfer function is similarto that of a notch filter with attenuation at high frequencies.

It is instructive to look at the proposed circuit in terms of it'sThevenin equivalent. With the device open-circuited, the Theveninvoltage can be seen to be v_(s). Based on mathematical circuit analysisthe Thevenin impedance is defined by:

$\begin{matrix}{Z_{TH} = \frac{{sL}_{m\; 1}Z_{RC}}{{s\left( {L_{m\; 2} - L_{m\; 1}} \right)} + Z_{RC}}} & (10)\end{matrix}$

Using the parameters from before, the plot of Thevenin impedance isshown in FIG. 6. At low frequencies, this is seen as inductive and hasthe value L_(m1). This is seen from equation (10) and Z_(RC) is anopen-circuit at low frequencies. At high frequencies, the Theveninimpedance becomes a negative resistor. Thus, considering the Theveninequivalent, applying a transient or high-frequency fault results incurrent flow back to the source which causes the source (or SCR) currentto go to zero. The DC circuit breaker presented herein automaticallyresponds to faults. A comparison of various prior art DC breakertopologies is shown in Table II. The “+” symbol in a column indicateswhere that circuit has an advantage, the“−” indicates a disadvantage,and the “0” represents a neutral comparison.

TABLE II Comparison of the proposed breaker to z-source variantsModified New Classic Series series series Proposed Common source/load− + + + + ground Low-pass filter transfer − − + + 0 function Invariantto load steps − − − + + No ringing in source + − − − + current

As can be seen, the classic z-source breakers have a number oflimitations. A common ground between the source and load is establishedwith the series design but then the source current would ring after theSCR switched off. This is an inconvenience since the source current canring up to a large value and inductance must be increased to limit thisringing. The modified series design also addresses the common ground andfurther has the desirable property that its transfer function has alow-pass form. Up to this point, all the designs could mistake a stepchange in load of more than 100% as a fault. The new series designeliminated this by providing an additional branch for the fault current.However, the source current ringing was still problematic. The inventiveDC circuit breaker can be seen to have all of the advantages listed inTable II. Furthermore, the inventive DC circuit breaker has much fewercomponents.

Based on the parameters of Table I, a detailed simulation was carriedout with a 100V source voltage and a purely resistive load. FIG. 7 showsthe source and load currents when the load is stepped from 50Ω to 16.7Ω.The variables are the same as those labeled in FIG. 2. As can be seen,the load current steps from 2 A to 6 A. This causes a step in capacitorcurrent which reflects back to the source current causing it to dip, butnot quite to zero. In fact, applying the criteria (6) with I_(o)=2 A andthe turns ratio given in Table I, states that a change of output currentby Δi_(o)>5.83 A would cause the DC circuit breaker to switch off. Thisindicates that the output current can step from 2 A up to 7.83 A withoutswitching the DC circuit breaker off. Therefore, the SCR stays on andthe source current goes to 6 A after the transient.

FIG. 8 shows the response of the inventive DC circuit breaker to afault. In this study, the source voltage is 100V and the load resistanceis 16.7Ω. A bolted fault occurs at the output which is represented by a10 m∧ resistance. As the output current starts to rise, the currentreflected in the transformer causes the source current to directly go tozero in microseconds. After the SCR switches off, the load current goesup to over 100 A as the capacitor discharges. The SCR voltage first goespositive and it is thus reverse biased for about 100 μs; allowing theSCR to completely turn off. When the SCR voltage goes negative and isequal in magnitude to the source voltage, the diode switches on stoppingthe resonance.

An example DC circuit breaker, prepared in accordance with theparameters of Table I, is described as follows. In the circuit, thetransformer connections are wound around the capacitor for better volumedensity. The magnetic field will be unaffected by the capacitor and theeffective air-core inductor will not experience saturation duringtransients. The SCR can be to the right and the resistor at the bottomof the board. The top half of the board contains voltage and currenttransducers which are used only for obtaining waveforms.

FIG. 9 shows the source and output current in response to a step changein load. The output current can be seen to step from 2 A to 6 A. Thetransient component of this current is reflected through the transformercausing the source current to dip. However, since the current does notgo to zero, the SCR continues to conduct. After a transient within thecircuit, the source current matches the load current.

FIG. 10 shows measured waveforms of the inventive DC circuit breaker inresponse to a fault. The source current is seen to go to zero; at whichtime the SCR switches off. The output current reflects the fault currentwhich increases to about 100 A until the output voltage drops causingthe current to go to zero. The last trace shows the SCR voltage. Aftergoing off, the SCR is reverse biased for about 100 microseconds, whichis longer than the total turn-off time of the SCR.

FIG. 11 shows an inventive DC circuit breaker inserted into amedium-voltage DC system. The RC impedance is replaced with a purecapacitance. In addition, a charging resistor R_(c) with an accompanyingdiode is in series. The purpose of the charging resistor is to initiallycharge the capacitor. That is, when starting, or re-energizing, thesource voltage is established then the SCR, labeled S₁, is gated on.This causes a charging of the capacitor through the transformer andcharging resistor. The desired charging time can be set using the timeconstant formed by C and R_(c). Furthermore, the charging resistorlimits the initial capacitor surge current. With the diode in parallel,the charging resistor is bypassed during fault operation and the DCcircuit breaker responds as described above.

An embodiment of the DC circuit breaker includes a switch-off SCR,labeled S₂. This adds an important feature to the DC circuit breaker inthat it allows the circuit to be used as a DC switch. Duringsteady-state operation, with the capacitor charged, gating on S₂discharges the capacitor into the secondary winding causing the DCcircuit breaker to switch off. Therefore, the DC circuit breaker can bepurposely switched off by gating S₂. Then switched on again by gatingS₁. It is important to note that this added switch has the same effectas crow-baring the output. However, since the switch is not placed atthe output, it will not cause a short-circuit.

For the purposes of demonstration, a medium-voltage DC (MVDC) systemwith a source voltage of v_(S)=1000 V and a power level of 100 kW(R—_(I)=10 fl) wherein the source has an inductance of L_(s)=10 pH wasprepared. The design of the DC circuit breaker was carried out byselecting a number of turns, turns ratio, and wire diameter sufficientto support full current resulting in a wire with a cross sectional areais 0.42 cm². In this case, a leakage inductance of 10% is assumed. Thetransformer was made as an air core a solenoid structure having a radiusof about 10 cm with a mass of 13 kg and a volume of 16 L. Table IIIshows the transformer parameters.

The breaker capacitance was set to 100 uF and the charging resistance isset to 100Ω providing a capacitor charging current with a peak value of10 A based on v_(s)=1000 V and R_(C)=100Ω thereby providing a reasonablecharging time constant based on C=100 μF and R=100Ω.

For this design, a Vishay ST173S12EJ0-PbF SCR was used which hassufficient voltage and current ratings. The SCR is a fast turn-off typewith a total turn off time of t_(q)=25 μs.

TABLE III Parameters of the MVDC breaker design. N₁ = 40 r₁ = 10.3 mL_(l1) = 69 μH L_(m1) = 625 μH N₂ = 14 r₂ = 3.62 mΩ L_(l2) = 85 μHL_(m2) = 77 μH R_(c) = 100 Ω C = 100 μF V_(RRM) = 1200 V I_(TRMS) = 275A t_(q) = 25 us

FIG. 12 shows simulation results of the proposed DC circuit breakerdemonstrating switch-off capability. Initially, the DC circuit breakeris supporting a 30 kW load when the load is switched to 100 kW. As canbe seen, the source and output current step to rated load and the DCcircuit breaker does not switch off. This could be predicted using theturns ratio and equation (6). The voltage across the transformer v_(T)spikes to 500V. A measurement of this voltage could be used todifferentiate between a step change in load and a fault. At the end ofthe simulation, a gate signal is given to S₂. This causes the capacitorto discharge into the transformer secondary winding and, as expected,causes the inventive DC circuit breaker to switch off. Thus, this addedSCR can be used to purposely switch off the load.

FIG. 13 shows results of a simulation that is similar to that of FIG. 12except that the de circuit breaker switches off in response to a fault.As before, the dc circuit breaker does not respond to the step change inload. When the fault is applied, the output current surges, causing thede circuit breaker to switch off and the source current simply goes tozero. The transformer voltage V_(T) spikes to about 1 kV when the faultis applied. Thus, the voltage V_(T) may be of some use in indicatingfaults. As a control signal, a measure of V_(T) may be useful inremoving the signal to S₁, for autonomous operation. It may also proveto be useful in identifying faults that don't have rapid inception. Thevoltage across one inductor selected from said first inductor and saidsecond inductor of the transformer is utilized as a control signal forfault detection.

As DC sources and DC micro grids become more prevalent, a solution issought for DC switches and circuit breakers. Traditional methods reliedon over-sized AC breakers, hybrid breakers, and solid-state breakers.The inventive DC circuit breaker described herein is a variation on thesolid-state breaker, but has the added feature that it can automaticallyswitch off in response to faults. Furthermore, the turns ratio in thecircuit's transformer allows the designer to determine the amount oftransient current that will be identified as a fault; as opposed to astep change in load. Analysis, design, and laboratory measurementsdemonstrate the inventive DC circuit breaker's response to a step changein load and to a fault. The DC circuit breaker compares favorably torecent designs in that it has a common ground between source and load,is invariant to step changes in load, and does not produce ringingresonance in the source current.

The invention has been described with reference to the preferredembodiments without limit thereto. One of skill in the art would realizeadditional embodiments and improvements which are not specifically setforth herein but which are within the scope of the invention as morespecifically set forth in the claims appended hereto.

The following references are referred to herein and incorporated byreference:

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The invention claimed is:
 1. A DC circuit breaker for automaticallydetecting and isolating a fault between a source and a groundcomprising: a first inductor electrically connected on a first side to aload; at least one switch in electrical series with a second side ofsaid first inductor, such that said at least one switch is locatedbetween said source and said load; a second inductor magneticallycoupled to said first inductors; an electrical component electricallyconnected between a capacitor and a around; and a second switchelectrically connected between said first side of said second inductorand a junction of said capacitor and said electrical component, whereina first side of said second inductor is electrically connected to saidload, and wherein a second side of said second inductor is groundedthrough said capacitor.
 2. The DC circuit breaker of claim 1, whereinsaid switch is selected from a silicon-controlled rectifier, aninsulated-gate bipolar transistor, a metal-oxide semiconductorfield-effect transistor and a mechanical contact.
 3. The DC circuitbreaker of claim 2, wherein said switch is a silicon-controlledrectifier.
 4. The DC circuit breaker of claim 1, wherein when a faultoccurs, resonance is prevented by a diode.
 5. The DC circuit breaker ofclaim 1, wherein said electrical component is selected from a passivecomponent and an active component.
 6. The DC circuit breaker of claim 5,wherein said electrical component is selected from the group consistingof a resistor, a capacitor, a diode, a semi-conductor switch, amemresistor, a varistor and an inductor.
 7. The DC circuit breaker ofclaim 1, wherein said second switch is selected from asilicon-controlled rectifier, an insulated-gate bipolar transistor, ametal-oxide semiconductor field-effect transistor and a mechanicalcontact.
 8. The DC circuit breaker of claim 7, wherein said secondswitch is a silicon-controlled rectifier.
 9. The DC circuit breaker ofclaim 1, wherein voltage across one inductor selected from said firstinductor and said second inductor is utilized as a control signal forfault detection.